Motion stabilized image sensor, camera module and apparatus comprising same

ABSTRACT

An image sensor includes: an image obtainer configured to generate image information by converting received light into an electrical signal; a first detector configured to detect first time information regarding a first time at which the image obtainer acquires the image information; a second detector configured to receive a plurality of pieces of movement information indicating movements of the image obtainer, and detecting second time information regarding a second time at which at least one piece of movement information among the plurality of pieces of movement information is received. A single port is configured to output the image information, the first time information, output movement information selected from among the plurality of pieces of movement information, and the second time information regarding the selected output movement information.

CROSS-REFERENCE TO RELATED APPLICATIONS

This is a Continuation Application of U.S. application Ser. No.15/498,978, filed Apr. 27, 2017, which claims priority from KoreanPatent Application No. 10-2016-0099087, filed on Aug. 3, 2016 and KoreanPatent Application No. 10-2016-0120892, filed on Sep. 21, 2016 in theKorean Intellectual Property Office, the disclosures of which areincorporated herein by reference in their entireties.

BACKGROUND 1. Field

Methods and apparatuses consistent with example embodiments relate to animage sensor, a camera module and an apparatus including the same.

2. Description of Related Art

Camera modules including image sensors are commonly mounted inapparatuses used within a range of fields, such as mobile devices,drones, digital cameras, wearable devices, and automobiles. When imagesare obtained using image sensors, if camera modules including imagesensors or apparatuses including camera modules move, the quality ofimages obtained therewith may be degraded. In particular, camera modulesinstalled in apparatuses that frequently move may generate images withincreased degradation due to movements thereof. Therefore, processes ofcorrecting images obtained by image sensors need to be performed, inorder to compensate for the movements of camera modules or apparatuses.

SUMMARY

One or more example embodiments provide an image sensor, a camera moduleand an apparatus able to compensate for movements more precisely.

According to an aspect of an example embodiment, there is provided animage sensor including: an image obtainer configured to generate imageinformation by converting received light into an electrical signal; afirst detector configured to detect first time information regarding afirst time at which the image obtainer acquires the image information; asecond detector configured to receive a plurality of pieces of movementinformation indicating movements of the image obtainer, and detectsecond time information regarding a second time at which at least onepiece of movement information among the plurality of pieces of movementinformation is received; and a single port configured to output theimage information, the first time information, output movementinformation selected from among the plurality of pieces of movementinformation, and the second time information regarding the outputmovement information.

According to an aspect of another example embodiment, there is providedan image sensor including: an image obtainer configured to generateimage information by converting received light into an electrical signalbased on a plurality of control signals; a first detector configured tooutput the plurality of control signals, and detect first timeinformation regarding a first time at which the image obtainer acquiresthe image information using at least one among the plurality of controlsignals; a second detector configured to receive a plurality of piecesof movement information indicating movements of the image obtainer, anddetect second time information regarding a second time at which at leastone piece of movement information among the plurality of pieces ofmovement information is received; and an output interface configured tooutput the image information, the first time information, the at leastone piece of movement information, and the second time information.

According to an aspect of yet another example embodiment, there isprovided a camera module including: an optical unit including aplurality of lenses; a movement sensor configured to detect movement andgenerate a plurality of pieces of movement information based on thedetected movement; and an image sensor configured to generate imageinformation by converting light received through the optical unit intoan electrical signal, receive the plurality of pieces of movementinformation; and output, through a single port, the image information,first time information, information regarding a first time at which theimage information is obtained, at least one piece of movementinformation among the plurality of pieces of movement information, andsecond time information regarding a second time at which the at leastone piece of movement information is received.

According to yet another example embodiment, there is provided a cameramodule including: an optical unit including a plurality of lenses; amovement sensor configured to detect movement and output a plurality ofpieces of movement information based on the detected movement; and animage sensor configured to generate image information by convertinglight received through the optical unit into an electrical signal basedon a plurality of control signals, receive the plurality of pieces ofmovement information, detect first time information regarding a firsttime at which the image information is obtained; and output the imageinformation, the first time information, at least one piece of movementinformation, and second time information regarding a second time atwhich the at least one piece of movement information is received.

According to still yet another example embodiment, there is provided anapparatus including: a camera module including: an optical unitincluding a plurality of lenses; a movement sensor configured to outputa plurality of pieces of movement information based on detectedmovements; and an image sensor configured to generate image informationby converting light received through the optical unit into an electricalsignal, receive the plurality of pieces of movement information, andoutput, through a single port, the image information, first timeinformation regarding a first time at which the image information isobtained, at least one piece of movement information among the pluralityof pieces of movement information, and second time information regardinga second time at which the at least one piece of movement information isreceived; and a processor configured to receive the image information,the first time information, the at least one piece of movementinformation, and the second time information, and modify the imageinformation using the first time information, the at least one piece ofmovement information, and the second time information.

According to another example embodiment, there is provided an imagecompensation method of an imaging device, the image compensation methodincluding: generating image information based on received light;detecting first time information regarding a first time at which theimage information is generated; sensing a movement of the imagingdevice; detecting second time information regarding a second time atwhich the movement is sensed; and generating compensated image databased on the generated image information, the first time information,the movement, and the second time information. According to stillanother example embodiment, there is provided a non-transitory computerreadable recording medium having embodied thereon a program, which whenexecuted by a processor causes the processor to execute an imagecompensation method, the image compensation method including: generatingimage information based on received light; detecting first timeinformation regarding a first time at which the image information isgenerated; sensing a movement of the imaging device; detecting secondtime information regarding a second time at which the movement issensed; and generating compensated image data based on the generatedimage information, the first time information, the movement, and thesecond time information.

BRIEF DESCRIPTION OF DRAWINGS

The above, and other aspects, features, and advantages of the presentdisclosure will be more clearly understood from the following detaileddescription when taken in conjunction with the accompanying drawings, inwhich:

FIG. 1 is a block diagram illustrating a configuration of an apparatusaccording to an example embodiment;

FIG. 2 is a block diagram illustrating a configuration of an imagesensor according to an example embodiment;

FIG. 3 is a block diagram illustrating a configuration of an imagesensor according to an example embodiment;

FIGS. 4A, 4B, and 4C are diagrams illustrating operations of an imagesensor according to an example embodiment;

FIGS. 5A, 5B, and 5C are diagrams illustrating operations of an imagesensor according to an example embodiment;

FIG. 6 is a diagram illustrating a configuration of data output by animage sensor according to an example embodiment;

FIG. 7 is a block diagram illustrating a configuration of a processor ofan apparatus according to an example embodiment;

FIGS. 8A, 8B, and 8C are diagrams illustrating operations of a processorof an apparatus according to an example embodiment;

FIG. 9 is a diagram illustrating a configuration of a camera moduleaccording to an example embodiment; and

FIG. 10 is a block diagram illustrating a configuration of an apparatusaccording to an example embodiment.

DETAILED DESCRIPTION

FIG. 1 is a block diagram illustrating a configuration of an apparatusaccording to an example embodiment. The apparatus according to theexample embodiment may include a camera module 100 and a processor 200.The camera module 100 of FIG. 1 may include a movement sensor 110 and animage sensor 120.

The movement sensor 110 may continuously output pieces of movementinformation mov. The pieces of movement information may indicatemovements of the camera module 100. The pieces of movement informationmay be output through a serial peripheral interface (SPI), aninter-integrated circuit (I2C) interface, or an inter-integrated circuit(I3C) interface. The movement sensor 110 may also periodically outputthe pieces of movement information mov. Alternatively, the movementsensor 110 may periodically detect movements to generate the pieces ofmovement information, and then, may simultaneously output the generatedpieces of movement information (mov) to the image sensor 120. Themovement sensor 110 may output the pieces of movement information (mov)in response to a command or request output from the image sensor 120.The movement sensor 110 may also include a gyroscope sensor or anacceleration sensor. The gyroscope sensor or the acceleration sensor maybe an advanced sensor used for optical image stabilization (OIS), andmay also be a dedicated sensor calibrated for imaging. The movementsensor 110 may be disposed adjacent to the image sensor 120 of thecamera module 100, which may allow the image sensor 120 to properlyreflect movement of the camera module 100.

The image sensor 120 may obtain image information by converting receivedlight into an electrical signal, may receive pieces of movementinformation from the movement sensor 110, and may output data includingthe obtained image information and the received pieces of movementinformation. The image sensor 120 may have a single port outputting thedata. Movement information output together with the image informationmay also be selected from the pieces of movement information received bythe image sensor 120, based on an exposure time of pixels for imageacquisition. The data may also additionally include first timeinformation regarding a time at which the image sensor 120 obtains theimage information, and second time information regarding a time at whichthe movement information is received. The first time information and thesecond time information may be detected using the same time information,for example, the same clock signal or a signal output by a singlecounter.

The data may be output through a mobile industry processor interface(MIPI). In this case, the movement information, the first timeinformation or the second time information may be output together withthe image information in an embedded data format or general data formatof the MIPI.

When the image sensor 120 selects and outputs pieces of movementinformation, the second time information may include times when thepieces of movement information are respectively input. Informationregarding the times when the pieces of movement information are inputmay be transmitted from the image sensor 120 to the processor 200 whilebeing added to each of the pieces of movement information.

The image sensor 120 may obtain the first time information directlyusing a control signal controlling operations of the pixels. The controlsignal may include at least one of a shutter control signal controllingexposure of the pixels and a read signal reading information regardingan image obtained by the pixels.

The processor 200 may receive the data from the camera module 100, andmay correct the image using the selected pieces of movement information.

For example, the image information and the pieces of movementinformation may be output through a single port. In this case, thesingle port may be an MIPI port. Thus, a hardware configuration of theapparatus may be simplified, and furthermore, the image sensor 120 mayoutput the most accurate movement information to the processor 200.

According to an example embodiment, the image sensor 120 may alsoreceive movement information from the movement sensor 110, maysynchronize the received movement information with an exposure time ofthe pixels in the image sensor 120, and may provide the movementinformation to an external source. As described above, the movementsensor 110 may periodically output the movement information. Forexample, a time interval at which pieces of movement information areoutput by the movement sensor 110 may be constant. However, an exposuretime of the pixels of the image sensor 120 may vary, depending onsurroundings. Thus, it may be difficult to identify an exact exposuretime of the pixels of the image sensor 120, for example, an exposurestart time and an exposure end time, from outside of the image sensor120.

As a result, according to an example embodiment, the image sensor 120 asa main component may store movement information output by the movementsensor 110, such as the gyroscope sensor or the acceleration sensor,together with a time stamp, and may provide the stored movementinformation to an external processor, for example, the processor 200, atan identified exact exposure time in frame units. The movement sensor110 and the image sensor 120 may be connected to each other through anSPI, an I2C interface, or an I3C interface, and the image sensor 120 andthe external processor may be connected to each other through an MIPI.In this case, the movement information may be output together with imagedata in an embedded data format or general data format of the MIPI. Forexample, the image data and the movement information may be outputthrough a single port.

This may allow movement information most accurately synchronized with anexposure time of the image sensor 120 to be transmitted to an externalsource, and a movement compensation function such as an OIS function maybe implemented without changing a chip interface or a module connector.In other words, inter-chip timing mismatch that may occur when aseparate chip detecting movement information is used may be prevented,and information regarding movements of the camera module 100 at anaccurate exposure time of the pixels of the image sensor 120 may betransmitted to the external processor without changing a moduleconnector or a chip pad.

FIG. 2 is a block diagram illustrating a configuration of an imagesensor according to an example embodiment. An image sensor 121 accordingto an example embodiment may include an image obtainer 1211, an exposuretime detector 1221, a buffer 1231, and a data transmitter 1241.

The image obtainer 1211 may output an image signal. The image obtainer1211 may include a pixel array including a plurality of pixels. Theimage signal img output from the image obtainer 1211 may include aplurality of image frames.

The exposure time detector 1221 may detect an exposure time of thepixels. The exposure time detector 1221 may also provide the detectedexposure time to the data transmitter 1241. The exposure time mayinclude a time at which exposure of the pixels is complete. The exposuretime detector 1221 may detect the exposure time directly using a controlsignal controlling the pixels. For example, the control signal maycontrol exposure of pixels included in a single column of the pixelarray, and depending on a state of the control signal, the pixels mayremain in a shutter close or shutter open state. Thus, the exposure timedetector 1221 may detect a shutter close or shutter open time bydetecting a time at which the state of the control signal changes.

The buffer 1231 may store each of pieces of movement informationtogether with a time stamp. The time stamp may be information regardinga time at which each of the pieces of movement information mov isreceived. The time stamp may also be added to all or a portion of thepieces of movement information mov.

The data transmitter 1241 may output data including an image signal imgand movement information mov corresponding to an exposure time. Forexample, the data transmitter 1241 may select at least one piece ofmovement information mov indicating movements of the image sensor 121,using an exposure time received from the exposure time detector 1221,for example, a shutter close or shutter open time, a time stamp formovement information mov, and the pieces of movement information movstored in the buffer 1231, and may output the selected at least onepiece of movement information together with an image signal. Theselected at least one piece of movement information may include movementinformation received at a time closest to the shutter close time.

Further, in order to obtain the exposure time and the time stamp storedtogether with the movement information, the image sensor 121 may furtherinclude a counter functioning as a global clock.

The exposure time detector 1221 and the data transmitter 1241 may alsobe implemented by software. For example, the image sensor 121 mayinclude a processor to function as the exposure time detector 1221 andthe data transmitter 1241, using software.

FIG. 3 is a block diagram illustrating a configuration of an imagesensor according to an example embodiment. An image sensor 122 mayinclude an image obtainer 1212, a first detector 1222, a second detector1232, an output interface 1242, and a clock generator 1252. The outputinterface 1242 may include a first storage 1242-1 and a second storage1242-2.

The image obtainer 1212 may generate image information img by convertingreceived light into an electrical signal. The image obtainer 1212 maygenerate image information img, in response to receiving a controlsignal con from the first detector 1222. In more detail, the imageobtainer 1212 may include a pixel array including a plurality of pixelsarranged in a matrix configured to output a voltage according to anamount of received light. In this case, the control signal con mayinclude shutter control signals or read signals for respective rows ofthe pixel array. For example, the pixels included in the respective rowsof the pixel array may receive light, depending on a state of acorresponding shutter control signal. For example, the pixels may remainin a shutter open or shutter close state, depending on the state of theshutter control signal. The pixels included in the respective rows ofthe pixel array may also output a voltage according to an amount oflight received depending on a state of a corresponding lead signal.

The first detector 1222 may output the control signal con to the imageobtainer 1212, may receive information regarding the current time, andmay detect information regarding a time at which the image obtainer 1212generates the image information img using the received control signalcon and information regarding the current time. For example, the firstdetector 1222 may detect the information regarding the current timeinput when the state of the control signal con changes as theinformation regarding the time at which the image obtainer 1212generates the image information img. The information regarding the timeat which the image obtainer 1212 generates the image information img mayinclude at least one of a shutter open time, a shutter close time, and aread end time for a first row of the pixel array, and of a shutter opentime, a shutter close time, and a read end time for a final row of thepixel array.

The second detector 1232 may receive pieces of movement information movand the information regarding the current time, and may detect theinformation regarding the current time input when the pieces of movementinformation mov are received as time information related to the piecesof movement information mov.

For example, the second detector 1232 may output movement informationmov_t to which the information regarding the current time input wheneach of the pieces of movement information mov is received is added as atime stamp, with respect to all of the received pieces of movementinformation mov. Alternatively, the second detector 1232 may outputmovement information mov_t to which the information regarding thecurrent time input when each of the pieces of movement information movis received is added as a time stamp, with respect to only a portion ofthe received pieces of movement information mov.

Each of the pieces of movement information mov may be periodicallyinput, or the pieces of movement information mov may be input in aplurality of groups. For example, in response to a signal output by animage sensor, a movement sensor may simultaneously output pieces ofmovement information mov to the image sensor. When the pieces ofmovement information mov are simultaneously input to the movementsensor, a time stamp for the latest movement information mov among thepieces of movement information mov may be generated using theinformation regarding the current time, and a time stamp for theremainder thereof may be generated using the time stamp for the latestmovement information mov and a movement detect period of the movementsensor.

The output interface 1242 may receive and store image information imgreceived from the image obtainer 1212, may receive and store timeinformation t_img related to the image information img received from thefirst detector 1222, may receive and store pieces of movementinformation mov_t to which time stamps are added from the seconddetector 1232, and may output the image information img received fromthe image obtainer 1212, the time information received from the firstdetector 12222 t_img, and the pieces of movement information mov treceived from the second detector 1232 to which the time stamps areadded. Also, the output interface 1242 may select a portion of thepieces of movement information mov_t received from the second detector1232 to which the time stamps are added using the time informationt_img, and may output the selected portion of the pieces of movementinformation mov t.

The second storage 1242-2 may store the pieces of movement informationmov_t to which the time stamps are added. The second storage 1242-2 as afirst-in first-out (FIFO) memory may be a static random access memory(SRAM).

The first storage 1242-1 may receive and store image information imgreceived from the image obtainer 1212, may receive and store timeinformation t_img related to the image information img received from thefirst detector 1222. The first storage 1242-1 may also store pieces ofmovement information mov_t selected from the pieces of movementinformation mov_t to which the time stamps are added based on the timeinformation t_img related to the image information img, and may outputthe stored selected pieces of movement information mov_t. For example,when a processor reads information stored in the first storage 1242-1,the stored information may be output as data. The first storage 1242-1may be an SRAM.

The clock generator 1252 may output the information regarding thecurrent time to the first and second detectors 1222 and 1232. The clockgenerator 1252 may be implemented as an oscillator or a counter.

FIGS. 4A, 4B, and 4C are diagrams illustrating operations of an imagesensor according to an example embodiment.

As illustrated in FIG. 1, the camera module 100 may have the movementsensor 110 and the image sensor 120 embedded together therein. Themovement sensor 110 may be a gyroscope sensor, and in this case, abidirectional (output) port of the gyroscope sensor may be connected tothe image sensor 120.

As described above, the image sensor 120 may have an additional counterprovided therein to function as a global clock.

As time stamps, global clocks at times t11, t21, and t31 when the pixelsof the image sensor 120 start to be exposed and at times t12, t22, andt32 when the exposure of the pixels is completed may be stored in imageframes, for example, first to third image frames, obtained by the imagesensor 120.

The image sensor 120 may store pieces of movement information in amemory, for example, the buffer 1231, and may store a global clock at atime at which each of the pieces of movement information is received asa time stamp. In an example, the time at which each of the pieces ofmovement information is received may be a value indicating that eachmovement information is information regarding movements of the cameramodule 100 at any point of time. For example, a time stamp of movementinformation mov_t12 may be t12, a time stamp of movement informationmov_t22 may be t22, and a time stamp of the movement information mov_t32may be t32.

After a single image frame is captured and then image data on the singleimage frame is output to an external source, the data transmitter 1241of the image sensor 120 may output a time stamp together with thecaptured single frame. For example, when the data transmitter 1241outputs image data on a first frame, the data transmitter 1241 mayoutput time stamps t11 and t12 together with the image data. A timestamp may be output as a footer, using an embedded data format of anMIPI.

Subsequently, the data transmitter 1241 may output movement informationcorresponding to the current frame, together with a time stamp for themovement information, at an idle time before outputting image data on anext frame. The movement information corresponding to the current framemay be selected using the time stamp. For example, when the currentframe is the first frame, the movement information mov_t12 having a timestamp t12 may be selected and output. Alternatively, when the currentframe is the first frame, pieces of movement information having a timestamp greater than or equal to the time stamp t12 and less than the timestamp t21 may be selected and output. In each case, the data transmitter1241 may output at least one piece of movement information selectedbefore outputting image data on the first frame and image data on asecond frame. The selected at least one piece of movement informationmay be output as a footer, using the embedded data format of the MIPI.In addition to the selected at least one piece of movement information,the time stamps t11 and t12 for the first frame and a time stamp for theselected at least one piece of movement information may be transmitted.

FIGS. 5A, 5B, and 5C are diagrams illustrating operations of an imagesensor according to an example embodiment.

As described above, the image obtainer 1211 of the image sensor 121 ofFIG. 2 and the image obtainer 1212 of the image sensor 122 of FIG. 3 mayinclude a plurality of pixels arranged in a matrix.

FIG. 5A is a diagram illustrating operations of the pixels.

First, a process of obtaining a first frame of image information isdescribed as follows.

At a time t11, pixels of a first row of the pixels may start to beexposed. For example, the pixels of the first row may remain in ashutter open state. At a time t12, the pixels of the first row of thepixels may be completely exposed. For example, the pixels of the firstrow may remain in a shutter close state. At a time t13, a read operationfor the pixels of the first row of the pixels may be completed. At atime t14, pixels of a final row of the pixels may start to be exposed.For example, the pixels of the final row may remain in a shutter openstate. At a time t15, the pixels of the final row of the pixels may becompletely exposed. For example, the pixels of the final row may remainin a shutter close state. At a time t16, a read operation for the pixelsof the final row of the pixels may be completed. The operations of thepixels may be controlled by a control signal (a shutter control signalor a read signal) applied to the image obtainer 1211 or 1212 illustratedin FIGS. 2 and 3.

A process of obtaining a second frame of the image information may besimilar to the process of obtaining the first frame.

In this case, as time information related to the obtaining of the imageinformation, the above-mentioned times t11 to t16 may be detected.

FIG. 5B illustrates pieces of movement information detected by an imagesensor, and FIG. 5C illustrates pieces of movement information to whichtime stamps t are added. FIG. 5C illustrates all of the pieces ofmovement information to which the time stamps t are added, but the timestamps t may also be added to only a portion of the pieces of movementinformation mov.

The image sensor may select and output the pieces of movementinformation, or a portion of the pieces of movement information to whichthe time stamps t are added, using time information related to theobtaining of the image information. For example, when the image sensoroutputs the first frame of the image information, the image sensor mayoutput pieces of movement information having a time stamp greater thanor equal to the time stamp t11 and less than the time stamp t21, orpieces of movement information to which the time stamps t are added.

FIG. 6 is a diagram illustrating a configuration of data output by animage sensor according to an example embodiment.

Data output by the image sensor according to an example embodiment mayinclude image information img, time information t_img related toobtaining of the image information img, and movement information mov_tselected on the basis of the time information t_img, and having a timestamp added thereto.

The time information t_img related to the obtaining of the imageinformation img may be detected directly using a control signalcontrolling pixels of the image sensor, and may include a shutter opentime, a shutter close time, and a read end time of pixels of a first rowof the pixels and a shutter open time, a shutter close time, and a readend time of pixels of a final of the pixels, as described above.

The selected movement information mov_t may be the whole or a portion ofpieces of movement information mov_t received by the image sensorbetween a shutter open time of pixels of a first row on the currentframe and a shutter open time of pixels of a first row on a framesubsequent to the current frame.

As described above, a time stamp may be added to only a portion ofpieces of movement information mov_t included in the data, and a timestamp may also be added to all of the pieces of movement informationmov_t included in the data.

Further, the data may also include a header which includes the imageinformation img, the time information t_img related to the obtaining ofthe image information img, and information regarding whether the timeinformation t_img is positioned in any portion of the data.

FIG. 7 is a block diagram illustrating a configuration of a processor ofan apparatus according to an example embodiment. A processor 200 mayinclude a comparator 201, a motion vector extractor 202, a corrector203, and an receiver 204.

FIGS. 8A, 8B, and 8C are diagrams illustrating operations of a processorof an apparatus according to an example embodiment. FIG. 8A illustratesdata received by the processor 200. FIG. 8B illustrates received imageinformation img_r output by the receiver 204. FIG. 8C illustratesreceived movement information mov_r output by the receiver 204.

Referring to FIGS. 7 and 8, the operations of the processor of theapparatus according to an example embodiment will be described below.

The receiver 204 may receive data, may output image information of thedata as received image information img_r, and may output movementinformation of the data as received movement information mov_r. Thereceiver 204 may extract the image information and the movementinformation from the data, using details of a header of the data.

The comparator 201 may compare a time stamp for the received movementinformation mov_r with a time stamp for the received image informationimg_r, and may select and output movement information to be used whenthe motion vector extractor 202 extracts a motion vector mov_v.

Subsequently, the motion vector extractor 202 may extract a motionvector mov_v, using the selected movement information.

Next, the corrector 203 may correct image data of a first frame, usingthe extracted motion vector mov v.

Such an operation may continue to be performed for a second frame and athird frame.

The comparator 201, the motion vector extractor 202, the corrector 203,and the receiver 204 may also be implemented by software. For example,the processor 200 may be implemented as a single application processor(AP), and the single AP may function as the comparator 201, the motionvector extractor 202, the corrector 203, and the receiver 204, usingsoftware.

The received movement information mov r may also include only a portionof pieces of movement information received by an image sensor.

Each of pieces of received movement information mov_r or a portionthereof may have a time stamp added thereto.

FIG. 9 is a diagram illustrating a configuration of a camera moduleaccording to an example embodiment. A camera module 101 may include anoptical unit 140 and an image sensor 131.

The optical unit 140 may include a cover 141 and a plurality of lenses142-1 and 142-2. The lenses 142-1 and 142-2 may move within the cover141. The cover 141 and the image sensor 131 may also be coupled to eachother in various manners.

The image sensor 131 may output image information, depending on anamount of light received through the optical unit 140. The image sensor131 may include a circuit and a pixel array stacked on a printed circuitboard (PCB).

Further, a movement sensor may be attached to a portion of the cameramodule 101. For example, the movement sensor may be attached to theimage sensor 131, and may also be attached to the cover 141.

FIG. 10 is a block diagram illustrating a configuration of an apparatusaccording to an example embodiment. An apparatus 1000 according to anexample embodiment may include a camera module 102 and a processor 202.

The camera module 102 may include a movement sensor and an image sensor.A configuration and operations of the image sensor included in thecamera module 102 may be the same as those illustrated in FIGS. 2, 3,4A, 4B, 4C, 5A, 5B, 5C and 6.

A configuration and operations of the processor 202 may be the same asthose illustrated in FIGS. 7, 8A, 8B and 8C.

FIG. 10 illustrates a mobile device as an apparatus according to anexample embodiment, but the apparatus according to an example embodimentmay be provided as various types of device, such as a drone, a digitalcamera, a wearable camera, or an automobile, to which a camera modulemay be attached.

According to an example embodiment, an image sensor may directly receivemovement information, and may buffer and output the received movementinformation. The image sensor may, for example, group, the movementinformation, based on an exposure time of pixels of the image sensor.The image sensor may also transmit the movement information to aprocessor, using an MIPI of the image sensor, other than a separateinterface for sending movement information. Further, the image sensormay include a counter functioning as a global clock, and may synchronizeimage information with movement information by adding time stamps to theimage information and the movement information, using the global clock.The processor may provide a higher quality image by using movementinformation packed in frame units to correct image information of acorresponding frame, with consideration of an exposure time.

As set forth above, according to example embodiments, an image sensor, acamera module, and an apparatus may provide a higher quality image.

As is traditional in the field of the present disclosure, exampleembodiments are described, and illustrated in the drawings, in terms offunctional blocks, units and/or modules. Those skilled in the art willappreciate that these blocks, units and/or modules are physicallyimplemented by electronic (or optical) circuits such as logic circuits,discrete components, microprocessors, hard-wired circuits, memoryelements, wiring connections, and the like, which may be formed usingsemiconductor-based fabrication techniques or other manufacturingtechnologies. In the case of the blocks, units and/or modules beingimplemented by microprocessors or similar, they may be programmed usingsoftware (e.g., microcode) to perform various functions discussed hereinand may optionally be driven by firmware and/or software. Alternatively,each block, unit and/or module may be implemented by dedicated hardware,or as a combination of dedicated hardware to perform some functions anda processor (e.g., one or more programmed microprocessors and associatedcircuitry) to perform other functions. Also, each block, unit and/ormodule of the embodiments may be physically separated into two or moreinteracting and discrete blocks, units and/or modules without departingfrom the scope of the inventive concepts. Further, the blocks, unitsand/or modules of the embodiments may be physically combined into morecomplex blocks, units and/or modules without departing from the scope ofthe inventive concepts.

While exemplary embodiments have been shown and described above, it willbe apparent to those skilled in the art that modifications andvariations could be made without departing from the scope of the presentdisclosure.

What is claimed is:
 1. A mobile device comprising: a camera module; andan application processor configured to receive image information, timeinformation, and movement information from the camera module, whereinthe camera module comprises: a movement sensor configured to detectmovement of the camera module; and an image sensor configured to obtainthe image information, to receive the movement information from themovement sensor, to output the movement information to the applicationprocessor, and to synchronize the movement information with the imageinformation using a global clock.
 2. The mobile device of claim 1,wherein the image sensor is configured to directly receive the movementinformation from the movement sensor.
 3. The mobile device of claim 2,wherein the movement sensor comprises a gyroscope sensor.
 4. The mobiledevice of claim 3, wherein the movement sensor is configured to outputthe movement information to the image sensor via a serial peripheralinterface.
 5. The mobile device of claim 3, wherein the movement sensoris configured to output the movement information to the image sensor viaan inter-integrated circuit (I2C) interface.
 6. The mobile device ofclaim 4, wherein the movement sensor is configured to periodicallyoutput the movement information to the image sensor.
 7. The mobiledevice of claim 4, wherein the camera module is configured to output theimage information, the time information, and the movement informationvia a single port.
 8. The mobile device of claim 7, wherein the singleport is a mobile industry processor interface (MIPI).
 9. The mobiledevice of claim 8, wherein the movement sensor is configured to outputthe movement information to the image sensor in response to a command orrequest output from the image sensor.
 10. The mobile device of claim 9,wherein the image sensor is configured to synchronize the movementinformation with the image information by adding time stamps to themovement information and the image information.
 11. A mobile devicecomprising: a camera module; and an application processor configured toreceive image information, time information, and movement informationfrom the camera module, wherein the camera module comprises: an imagesensor configured to obtain the image information, to output themovement information and the time information related to obtaining ofthe image information to the application processor, and to synchronizethe movement information with the image information using a globalclock; and a movement sensor configured to detect movement of the cameramodule, and to output the movement information to the image sensor inresponse to a command or request output from the image sensor, whereinthe movement information is selected based on the detected movement. 12.The mobile device of claim 11, wherein the movement sensor is configuredto output the movement information to the image sensor via aninter-integrated circuit (I2C) interface.
 13. The mobile device of claim12, wherein the camera module is configured to output the movementinformation via a single port.
 14. The mobile device of claim 13,wherein the single port is a mobile industry processor interface (MIPI).15. The mobile device of claim 14, wherein the image sensor isconfigured to directly receive the movement information from themovement sensor.
 16. A mobile device comprising: a camera module; and anapplication processor configured to receive image information andmovement information from the camera module, and to output a globalclock to the camera module, wherein the camera module comprises: animage sensor configured to obtain the image information, to output themovement information and time information related to obtaining of theimage information to the application processor, and to synchronize themovement information with the image information using the global clock;and a movement sensor configured to periodically detect movements of thecamera module to generate the movement information, and to output themovement information to the image sensor, wherein the movementinformation is selected based on the detected movement.
 17. The mobiledevice of claim 16, wherein the movement sensor is configured to outputthe movement information to the image sensor via an inter-integratedcircuit (I2C) interface.
 18. The mobile device of claim 17, wherein themovement sensor is configured to output the movement information to theimage sensor via a mobile industry processor interface (MIPI).
 19. Themobile device of claim 18, wherein the image sensor is configured todirectly receive the movement information from the movement sensor. 20.The mobile device of claim 16, wherein the image information and themovement information are output through a single port.